Lipid metabolism in large T47D human breast cancer spheroids: 31P- and 13C-NMR studies of choline and ethanolamine uptake.

31P- and 13C-NMR were used to determine the kinetics of choline and ethanolamine incorporation in T47D clone 11 human breast cancer cells grown as large (300 microns) spheroids. Spheroids were perfused inside the spectrometer with 1,2-13C-labeled choline or ethanolamine (0.028 mM) and the buildup of labeled phosphorylcholine (PC) or phosphorylethanolamine (PE) was monitored. To analyze the NMR kinetic data, it was assumed that each signal represents a weighted average of signal from the proliferating and non-proliferating compartments of the large spheroid. The average ATP pool size was 4 +/- 1 fmol/cell compared to 8 +/- 1 fmol/cell in small (150 microns) proliferating spheroids (P less than 0.0002). The average PC pool size at steady state was reduced to 11 +/- 6 fmol/cell compared to 22 +/- 8 (P less than 0.007). This could be correlated with an overall reduction of choline uptake in the non-proliferating spheroid fraction. The rate of the enzyme choline kinase was 0.3 fmol/(cell h) compared to 1.0 fmol/(cell h) (P less than 0.0001) for proliferating cells. The rate constant of CTP:phosphocholine cytidyltransferase (0.05 h-1) was not significantly altered, but the rate of the enzyme was reduced from 1.3 to 0.2-0.5 fmol/(cell h). The pool size of PE in medium containing serum ethanolamine (1.7 microM) was approximately the same (15 fmol/cell) in small and large spheroids. In the presence of high ethanolamine (0.028 mM) the average PE level decreased slightly (11 fmol/cell) and the rate of the enzyme ethanolamine kinase in the non-proliferating fraction was 0.7 fmol/(cell h) versus 1.0 fmol/(cell h) in the proliferating cells (P less than 0.07). The rate constant of CTP:phosphoethanolamine cytidyltransferase (0.07 h-1) was not significantly altered but the corresponding reaction rate was reduced from 1.4 to 0.2-0.8 fmol/(cell h). The kinetics of choline incorporation did not alter in the presence of 0.028 mM ethanolamine.     

Lipid metabolism in T47D human breast cancer cells: 31P and 13C-NMR studies of choline and ethanolamine uptake.

31P and 13C-NMR were used to determine the kinetics of choline and ethanolamine incorporation in T47D clone 11 human breast cancer cells grown as small (150 microns) spheroids. Spheroids were perfused inside the spectrometer with 1,2-13C-labeled choline or 1,2-13C-labeled ethanolamine (0.028 mM) and the buildup of labeled phosphoryl-choline (PC) or phosphorylethanolamine (PE) was monitored. Alternatively the PC and GPC pools were prelabeled with 13C and the reduction of label was monitored. 31P spectra were recorded from which the overall energetic status as well as total pool sizes could be determined. The ATP content was 8 +/- 1 fmol/cell, and the total PC and PE pool sizes were 16 and 14 fmol/cell, respectively. PC either increased by 50% over 24 h or remained constant, while PE remained constant in medium without added ethanolamine but increased 2-fold within 30 h in medium containing ethanolamine, indicating a dependence on precursor concentration in the medium. The 31P and 13C data yielded similar kinetic results: the rate of the enzymes phosphocholine kinase and phosphoethanolamine kinase were both on the order of 1.0 fmol/cell per h, and the rate constants for CTP:phosphocholine cytidyltransferase and CTP:phosphoethanolamine kinase were 0.06 h-1 for both enzymes. The kinetics of choline incorporation did not alter in the presence of 0.028 mM ethanolamine indicating that they have non-competing pathways.     

Inhibition of proliferation of T47D human breast cancer cells: Alterations in progesterone receptor and p53 tumor suppressor protein

We have investigated the influence of three structurally different but functionally related compounds [1, 10 ortho-phenanthroline (phenanthroline), Rifampicin and aurin tricarboxylic acid (ATA)] on the rate and the extent of proliferation of progesterone-responsive T47D human breast cancer cells. These compounds have previously been used in this laboratory and have been shown to modulate properties of nucleic acid binding proteins. Because p53 and the progesterone receptor (PR) are both DNA binding proteins that appear to regulate proliferation of breast cells, alterations in T47D cell p53 and PR levels were examined to determine their relevance in cell proliferation. T47D cells were grown in the absence of phenol red and in the presence of 5% fetal calf serum with or without charcoal stripping in the presence of the inhibitors. The rate of proliferation of cells grown in Rifampicin containing medium exhibited nearly 70% inhibition. Phenanthroline, a known metal chelator, was an effect ive inhibitor of proliferation at 3 mM reducing the cell number by more than 75%. ATA (0.24–2.4 µg/ml) inhibited the growth of the cells by nearly 50%. Analysis of the mechanism of action of these compounds revealed that treatment with these compounds caused specific changes in the molecular composition of T47D cell PR. Whereas ATA caused increased stability of PR isoforms, Rifampicin induced a upshift in the mobility of PR in SDS gels – a phenomenon associated with hyperphosphorylation of steroid receptors (SRs). Phenanthroline treatment (> 2 mM) caused a complete down-regulation of PR and the tumor suppressor protein, p53. The downregulation of p53 paralleled the changes in the molecular composition of PR. We propose that the inhibition of T47D cell proliferation by phenanthroline, Rifampicin and ATA results from a number of cellular changes that include regulation of p53 and PR. (Mol Cell Biochem 175: 81–89, 1997)